Structure of infiltration pipe

ABSTRACT

An improved structure of infiltration pipe includes an infiltration pipe made of a flexible material. The infiltration pipe has a surface suffused with fine infiltration holes. A mesh layer is wrapped on an external part of the infiltration pipe, and includes a plurality of reinforcing stripes combined with the infiltration pipe to form a plurality of mesh holes. Therefore, the mesh layer is firmly wrapped on the external part of the infiltration pipe, so as to enhance strength of the infiltration pipe, such that the infiltration pipe bears a larger tension and gravity, thereby forming a reinforced infiltration pipe structure.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an improved structure of infiltration pipe, which has an elastic mesh layer combined with an external part of an infiltration pipe, so as to form a plurality of mesh holes, thereby reinforcing strength of the infiltration pipe and having an efficacy of being bent without blocking a water flow.

2. Related Art

Accordingly, an infiltration pipe structure usually used in the conventional art is mainly formed by a pipe body having a surface suffused with fine holes, such that a water flow may be sprayed to the ground or the roof through the fine holes in an open manner.

However, the conventional infiltration pipe formed by injection molding a single plastic material is embedded in the soil or the roof, exposed to the environment without any reinforcing structure measure, such that during using, the pipe body may be curved, depressed, cracked, and broken etc. due to a weak strength and a poor elasticity, and the water cannot be continuously sent or a great amount of water is leaked.

In order to solve the above problems in the conventional art, with creation ideas and designs based on long-term experiences, the inventor puts forward the present invention after discussions, sample experiments, and various modifications.

SUMMARY OF THE INVENTION

The present invention is mainly directed to an improved structure of infiltration pipe capable of enhancing strength of the infiltration pipe and being bent without blocking a water flow

In order to achieve the objective, the present invention provides an improved structure of infiltration pipe, which includes an infiltration pipe made of a flexible material. The infiltration pipe has a surface suffused with fine infiltration holes. A mesh layer is wrapped on an external part of the infiltration pipe, so as to form a reinforced infiltration pipe structure.

During implementation, the mesh layer includes a plurality of reinforcing stripes, which are obliquely interlaced, so as to form quasi-quadrangle (for example, rhombic) mesh holes.

During the implementation, the mesh layer and the infiltration pipe are combined with each other, so as to be integrally formed. The method for combining the mesh layer and the infiltration pipe includes that the mesh layer is combined with the infiltration pipe by injection molding a plastic material, or the mesh layer is adhered to the infiltration pipe.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully understood from the detailed description given herein below for illustration only, and thus are not limitative of the present invention, and wherein:

FIG. 1 is a three-dimensional view of the present invention;

FIG. 2 is a cross-sectional view of the present invention; and

FIG. 3 is a schematic view of a using state of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIGS. 1 to 3, a preferred embodiment of an improved structure of infiltration pipe according to the present invention is shown.

FIG. 1 is a three-dimensional exploded view of the present invention. An improved structure 10 of infiltration pipe according to the present invention includes an infiltration pipe 11 made of a flexible material. The infiltration pipe 11 has a surface suffused with fine infiltration holes. A mesh layer 12 is wrapped on an external part of the infiltration pipe 11.

The mesh layer 12 includes a plurality of reinforcing stripes 121. The reinforcing stripes 121 are elastic. During disposition, the reinforcing stripes 121 are obliquely interlaced or horizontally spaced on the infiltration pipe, so as to form mesh holes 122. In this embodiment, for example, the reinforcing stripes 121 are obliquely interlaced on the infiltration pipe 11, so as to form the quasi-quadrangle (for example, rhomboid) mesh holes 122, such that the surface of the infiltration pipe 11 is exposed through the mesh holes 122.

The mesh layer 12 and the infiltration pipe 11 are combined with each other, so as to be integrally formed, thereby achieving a reinforcing function. The method for combining the mesh layer 12 and the infiltration pipe 11 includes that the mesh layer 12 is combined with the infiltration pipe 11 by injection molding a plastic material, or the mesh layer 12 is adhered to a contact part 13 of the infiltration pipe 11 (as shown in FIG. 2), which all fall within the scope of the present invention.

FIG. 3 is a schematic view of a using state of the present invention. Referring to FIG. 3, the improved structure 10 of infiltration pipe is disposed according to demands of sites in a fixed region. Further, the improved structure 10 of infiltration pipe may be selectively suspended, laid, or embedded in the ground, such that the regions requiring irrigation are all surrounded by the improved structure 10 of infiltration pipe. Therefore, when water flows through the infiltration pipe 11, the water infiltrates through the infiltration holes to form water globules, and the water globules drop through the mesh holes 122 of the mesh layer 12, so as to achieve an objective of continuously spraying water for moisturizing or heat dissipation. Therefore, no matter the improved structure 10 of infiltration pipe is suspended, laid, or embedded in the ground, the mesh layer 12 on the external part contacts with and rubs against the ground, so the infiltration pipe 11 is not easily worn. The infiltration pipe 11 and the mesh layer 12 are integrally formed, and the infiltration pipe 11 and the mesh layer 12 are not easily separated from each other, thus the strength of the infiltration pipe 11 is relatively enhanced and a reinforcing body is formed. Therefore, the infiltration pipe 11 bears a preferred tension and gravity without being easily damaged by an external force, and has an efficacy of being bent without blocking the water flow.

To sum up, the present invention is an innovative structure, has improved creation contents, and achieves industrial applicability and inventive steps. The present invention never appears in any publications, and has novelty, thus it is a new and useful utility invention. 

1. An improved structure of infiltration pipe, comprising an infiltration pipe made of a flexible material, wherein the infiltration pipe has a surface suffused with fine infiltration holes, and a mesh layer is wrapped on an external part of the infiltration pipe, so as to form a reinforced infiltration pipe structure.
 2. The improved structure of infiltration pipe according to claim 1, wherein the mesh layer comprises a plurality of reinforcing stripes.
 3. The improved structure of infiltration pipe according to claim 2, wherein the reinforcing stripes are interlaced.
 4. The improved structure of infiltration pipe according to claim 3, wherein the reinforcing stripes are obliquely interlaced, so as to form quadrangle mesh holes.
 5. The improved structure of infiltration pipe according to claim 1, wherein the mesh layer and the infiltration pipe are combined with each other, so as to be integrally formed.
 6. The improved structure of infiltration pipe according to claim 5, wherein the mesh layer is combined with the infiltration pipe by injection molding a plastic material.
 7. The improved structure of infiltration pipe according to claim 6, wherein the mesh layer comprises a plurality of reinforcing stripes.
 8. The improved structure of infiltration pipe according to claim 7, wherein the reinforcing stripes are interlaced.
 9. The improved structure of infiltration pipe according to claim 8, wherein the reinforcing stripes are obliquely interlaced, so as to form quadrangle mesh holes.
 10. The improved structure of infiltration pipe according to claim 5, wherein the mesh layer is adhered to the infiltration pipe.
 11. The improved structure of infiltration pipe according to claim 10, wherein the mesh layer comprises a plurality of reinforcing stripes.
 12. The improved structure of infiltration pipe according to claim 11, wherein the reinforcing stripes are interlaced.
 13. The improved structure of infiltration pipe according to claim 12, wherein the reinforcing stripes are obliquely interlaced, so as to form quadrangle mesh holes. 